基于载波相位差分的GPS载体姿态测量系统算法研究
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摘要
利用GPS载波相位进行载体姿态测量是近年来新发展起来的一项GPS应用技术,与传统的惯性导航姿态测量系统相比,不仅能够提供载体的位置、速度和姿态信息,而且具有信息不随时间发散的优点,是其他姿态测量系统无法比拟的,已经广泛应用于航路导航、精密着陆、自动驾驶等领域。本文针对GPS姿态测量系统的关键技术进行研究,对进一步拓展GPS技术的应用具有重要的实用意义。
本文首先通过对载波相位测量技术和基线姿态信息解算技术的讨论,介绍了GPS载波相位测量及定位原理,包括载波相位测量的观测量、观测方程及其线性化、载波相位相对定位原理等,确定了姿态测量的方式;对影响系统测量精度的各类误差源进行了分析,为后续确定载体姿态解算算法奠定了基础;在利用GPS载波相位进行姿态测量时,要确定准确的基线向量,关键是要保证载波相位信息的准确性。快速准确的获得载波相位的初始整周模糊度,是获得高精度定位的关键因素,是GPS姿态测量的关键问题。本文对常用模糊度的解算方法进行对比分析,确定系统模糊度解算方案,进行详细论述并对算法的有效性进行仿真验证。
周跳是GPS载波相位测量过程中特有的问题。如果能够探测出周跳在何时发生、在哪个载波发生以及周跳值的大小,就可以对周跳发生时刻及其后续每个观测历元的载波相位值进行改正,将其恢复为正确的计数。本文对常用的周跳探测与修复方法进行对比分析,在此基础上提出了一种基于拟合思想的周跳探测与修复方法,用以解决电离层残差法检测周跳时的多值性问题,对该算法的实用性与有效性进行验证;之后,本文对常用载体姿态测量算法进行对比分析,确定系统的姿态解算算法并进行仿真研究,验证算法的可行性。
在GPS姿态测量过程中,由于需要解算的导航信息类型很多,对每种导航信息的解算都需要对相同文件信息的数据进行反复处理、计算,过程十分繁琐,同时,也需要有一个软件平台,能够将每种导航信息的解算和相应的数据处理进行模块化处理。最后采用面向对象的MFC编程技术,对GPS姿态测量系统进行软件设计与实现,软件的设计为用户提供友好的界面,增强人机交互功能,能够对系统的关键算法进行仿真验证,提高系统的解算效率,为进一步对GPS姿态测量系统的研究提供了良好的仿真平台。
Attitude determination by using GPS carrier phase is a new area of application of GPS recently. Comparing with the traditional attitude determination methods by INS (inertial navigation system), the information of position, velocity and attitude can be obtained by GPS attitude determination system, also do not divergent with time. And this advantage makes GPS being good at attitude determination than others. Now the method has being used in the fields such as route navigation, precise landing and automatic driving and so on. The key technologies of GPS attitude measurement system have been studied in this paper, which give a basic research on the extending the application of GPS technology.
Based on the research of the carrier phase determination technology and the baseline attitude information solution technology, introduced the GPS carrier phase measurement and positioning principles, including the observations of carrier phase measurements, observation equations and theirs linearization, the principle carrier phase relative positioning, etc, confirmed the way of attitude measurement, on this basis leads to the basic principles of Attitude Determination, the main error sources which effect on the precision of the system have been analyzed, which laid a foundation for the following algorithm to vehicle attitude determination. During attitude determination using GPS carrier phase, the determination of baseline vector is necessary, and the key work is to ensure the accuracy of carrier phase information. Fast and accurate access to the initial carrier phase ambiguity is the key factor to obtain high-precision positioning, which is the key issue of GPS attitude determination. According to the comparation and analyzation of common solution methods of integer ambiguity, a simulation result has been given in this paper to prove the method which based on the integer ambiguity solution method of the attitude measurement system has been determined is efficiency.
Cycle slip is a peculiar problem in the GPS carrier phase measurement process, and a key issue of GPS attitude determination. If the cycle slip occurring time and value can be detected, the observation value will be easier corrected at the right epoch, and restore the correct count. By analyzing and comparation the common methods of cycle-slip'detection and repairation, a good solution method of multi-valued problem of the ionospheres remnant method has been given, a simulation result has given to prove the new method is efficiency and feasible.
In the process of GPS attitude determination, there are many types of navigation information need to solve, to solve each kind of navigation information needs to the same data process and calculation repeatedly, the process is very cumbersome, at the same time, a software platform is also needed which can deal each kind of navigation information and corresponding data processing with module processing. In the last part of the paper the GPS attitude determination software system has been designed based on MFC. A friendly platform has been shown on the computer, and the key algorithms of GPS attitude measurement can be simulated and verified, which not only raising the solution speed but also showing a friendly simulation platform for the further researching of GPS attitude measurement system.
本文首先通过对载波相位测量技术和基线姿态信息解算技术的讨论,介绍了GPS载波相位测量及定位原理,包括载波相位测量的观测量、观测方程及其线性化、载波相位相对定位原理等,确定了姿态测量的方式;对影响系统测量精度的各类误差源进行了分析,为后续确定载体姿态解算算法奠定了基础;在利用GPS载波相位进行姿态测量时,要确定准确的基线向量,关键是要保证载波相位信息的准确性。快速准确的获得载波相位的初始整周模糊度,是获得高精度定位的关键因素,是GPS姿态测量的关键问题。本文对常用模糊度的解算方法进行对比分析,确定系统模糊度解算方案,进行详细论述并对算法的有效性进行仿真验证。
周跳是GPS载波相位测量过程中特有的问题。如果能够探测出周跳在何时发生、在哪个载波发生以及周跳值的大小,就可以对周跳发生时刻及其后续每个观测历元的载波相位值进行改正,将其恢复为正确的计数。本文对常用的周跳探测与修复方法进行对比分析,在此基础上提出了一种基于拟合思想的周跳探测与修复方法,用以解决电离层残差法检测周跳时的多值性问题,对该算法的实用性与有效性进行验证;之后,本文对常用载体姿态测量算法进行对比分析,确定系统的姿态解算算法并进行仿真研究,验证算法的可行性。
在GPS姿态测量过程中,由于需要解算的导航信息类型很多,对每种导航信息的解算都需要对相同文件信息的数据进行反复处理、计算,过程十分繁琐,同时,也需要有一个软件平台,能够将每种导航信息的解算和相应的数据处理进行模块化处理。最后采用面向对象的MFC编程技术,对GPS姿态测量系统进行软件设计与实现,软件的设计为用户提供友好的界面,增强人机交互功能,能够对系统的关键算法进行仿真验证,提高系统的解算效率,为进一步对GPS姿态测量系统的研究提供了良好的仿真平台。
Attitude determination by using GPS carrier phase is a new area of application of GPS recently. Comparing with the traditional attitude determination methods by INS (inertial navigation system), the information of position, velocity and attitude can be obtained by GPS attitude determination system, also do not divergent with time. And this advantage makes GPS being good at attitude determination than others. Now the method has being used in the fields such as route navigation, precise landing and automatic driving and so on. The key technologies of GPS attitude measurement system have been studied in this paper, which give a basic research on the extending the application of GPS technology.
Based on the research of the carrier phase determination technology and the baseline attitude information solution technology, introduced the GPS carrier phase measurement and positioning principles, including the observations of carrier phase measurements, observation equations and theirs linearization, the principle carrier phase relative positioning, etc, confirmed the way of attitude measurement, on this basis leads to the basic principles of Attitude Determination, the main error sources which effect on the precision of the system have been analyzed, which laid a foundation for the following algorithm to vehicle attitude determination. During attitude determination using GPS carrier phase, the determination of baseline vector is necessary, and the key work is to ensure the accuracy of carrier phase information. Fast and accurate access to the initial carrier phase ambiguity is the key factor to obtain high-precision positioning, which is the key issue of GPS attitude determination. According to the comparation and analyzation of common solution methods of integer ambiguity, a simulation result has been given in this paper to prove the method which based on the integer ambiguity solution method of the attitude measurement system has been determined is efficiency.
Cycle slip is a peculiar problem in the GPS carrier phase measurement process, and a key issue of GPS attitude determination. If the cycle slip occurring time and value can be detected, the observation value will be easier corrected at the right epoch, and restore the correct count. By analyzing and comparation the common methods of cycle-slip'detection and repairation, a good solution method of multi-valued problem of the ionospheres remnant method has been given, a simulation result has given to prove the new method is efficiency and feasible.
In the process of GPS attitude determination, there are many types of navigation information need to solve, to solve each kind of navigation information needs to the same data process and calculation repeatedly, the process is very cumbersome, at the same time, a software platform is also needed which can deal each kind of navigation information and corresponding data processing with module processing. In the last part of the paper the GPS attitude determination software system has been designed based on MFC. A friendly platform has been shown on the computer, and the key algorithms of GPS attitude measurement can be simulated and verified, which not only raising the solution speed but also showing a friendly simulation platform for the further researching of GPS attitude measurement system.
引文
[1]谢钢.GPS原理与接收机设计[M].电子工业出版社,2009:1-5页,72-77页,129-134页,108-113页
[2]贺智轶.基于GPS动态载体姿态测量系统的研究与应用[D].武汉理工大学硕士学位论文.2006:1页
[3]马鲲.GPS船舶姿态测量技术研究[D].大连海事大学硕士学位论文.2004:1页
[4]韩慧群.GPS姿态测量系统研究与开发[D].哈尔滨工程大学硕士学位论文.2005:2-3页
[5]李跃.导航与定位(第二版)[M].国防工业出版社,2008:20-21页,112-115页
[6]伍岳.第二代导航卫星系统多频数据处理理论及应用[D].武汉大学硕士学位论文.2005:3-4页
[7]王海涛.基于北斗双星定位系统的精密快速定向技术研究[D].国防科学技术大学硕士学位论文.2006:6-9页
[8]吴美平,逯亮清.北斗双星系统车辆定向技术[J].国防科技大学学报,2006,(03):612-614页
[9]孙希延,纪元法,施浒立.基于GPS的新测姿算法[J].全球定位系统,2006,(03):56-59页
[10]刘鹏辉.GPS姿态测量及整周模糊度技术研究[D].中北大学硕士学位论文.2007:5-6页,4页
[11]赵文晔.基于双天线的GPS测姿系统研究[D].苏州大学硕士学位论文.2009:3页
[12]刘瑞华,张鹏.基于改进LAMBDA算法的GPS载波相位测姿技术研究[J].航天控制,2010,(03):98-102页
[13]王艳,伍吉仓,胡丛玮.一种GPS整周模糊度解可靠性的估计方法[J].大地测量与地球动力学,2009,(05):27-30页
[14]田湘,范胜林,刘建业.基于GPS的多基线姿态系统研究[J].航天控制,2008,(02):23-26页
[15]张健.基于GPS的航天器姿态确定研究[D].哈尔滨工业大学硕士学位论文.2009:4-5页
[16]Juang J C, Huang G S. Development of GPS-based attitude determination algorithms. 1997 (03):201-205P
[17]张守信.GPS技术与应用[M].国防工业出版社,2004:6页,127-144页,192-198页,111-112页
[18]韦峰.GPS测量的应用研究[D].西安科技大学硕士学位论文.2007:6-7页
[19]刘若普.GPS三维姿态测量技术研究[D].上海交通大学硕士学位论文.2008:6-8页
[20]Phatak M S. Recursive method for optimum GPS strellite selection[J]. IEEE Transactions of Aerospace and Electronic Systems,2001,37 (2):751-754P
[21]陈石磊.GPS载波相位定位技术的研究[D].西安电子科技大学硕士学位论文.2008:6页
[22]郭婧.基于GPS的姿态测量技术研究[D].哈尔滨工程大学硕士学位论文.2009:12-14页
[23]许江宁,朱涛,卞鸿巍.GPS姿态测量技术综述[J].海军工程大学学报,2003,(03):17-22页
[24]郭兴华.GPS动态实时定位技术研究[D].哈尔滨工程大学硕士学位论文.2007:17-19页
[25]孙希延,纪元法,施浒立.基于GPS的新测姿算法[J].全球定位系统,2006,(03):39-41页
[26]崔铭.基于GPS的姿态测量算法研究[D].哈尔滨工程大学硕士学位论文,2008:32-33页
[27]陈琳.GPS姿态测量系统的研究[D].重庆大学硕士学位论文.2007:14-16页
[28]李康,黄胜,赵辉.GPS坐标系的转换及其在姿态求解中的应用[J].指挥控制与仿真,2008,(05):99-102页
[29]陆维维.GPS动态载波相位测量技术研究及应用[D].河海大学硕士学位论文.2006:17-18页
[30]许春明.GPS动态载波相位测量定位技术研究[D].哈尔滨工程大学硕士学位论文.2002:37-40页
[31]Ellis J F, Greswell G A. Interferometric attitude determination with the Global Positioning System. Journal of Guidance and Control.1979,12:523-527P
[32]赵琳.卫星导航系统[M].哈尔滨工程大学出版社,2001:121-124页
[33]刘基余.GPS卫星导航定位原理与方法[M].科学出版社,2006:369-376页
[34]杨铁军.GPS实时姿态测量技术与多径误差研究[D].电子科技大学硕士学位论文.2003:18-20页
[35]刘军承.GPS姿态确定技术[D].华北工学院硕士学位论文.2002:39-42页
[36]Juang J C, Huang G S. Development of GPS-based attitude determination algorithms.1997, (03):42-46P
[37]廖向前,黄顺吉,张晓玲.GPS双基线载体姿态测量研究[J].航空学报,1998,(05):531-535页
[38]王惠南,应金栋.GPS载体姿态测量中的LAMBDA方法研究[J].航空学报,2001,(01):61-63页
[39]史琳.GPS整周模糊度及其在姿态测量中的应用研究[D].武汉理工大学硕士学位论文.2008:43-48页
[40]张旭.GPS载波相位定位算法研究与仿真[D].哈尔滨工程大学硕士学位论文.2007:45-47页
[41]王仁谦.GPS动态定位的理论研究[D].中南大学硕士学位论文.2004:39-44页
[42]李建文.GLONASS卫星导航系统及GPS/GLONASS组合应用研究[D].解放军信息工程大学硕士学位论文.2001:38-40页
[43]P.J.G.Teunissen, P.J.de Jonge, C.C.J.M.Tiberius. The least-squares ambiguity decorrelation austment:its performance on short GPS baselines and short observation spans, Journal of Geodesy 1997 (71):589-602
[44]郑庆晖,张育林.GPS姿态测量的载波相位整周模糊度快速解算[J].航空学报,2002,(03):113-116页
[45]Chang XW, Yang X, Zhou TY. MLAMBDA:A modified LAMBDA method for integer least-squares estimation. School of Computer Science, McGill UniveBity, 2005:1-20P
[46]林雪原,田淑荣,陈玉林.一种GPS整周模糊度的解算方法[J].海军航空工程学院学报,2008,(01):112-114页
[47]范胜林等.GPS姿态系统中周跳的检测及修复方法[J].数据采集与处理,2002,(1):50-53页
[48]李江卫.GPS相位观测值中周跳的探测与修复算法研究[D].武汉大学硕士学位论文.2004:31-34页
[49]Rizos.C, Lichtenegger.H and B.Hofinarm-Wellenhof. GPS-data proeessing for cycle-slip detection. International Association of Geodesy Symposium 102,1999 Edinburgh, Scotland,2-8 August 1989:57-68P
[50]李航征,张小红.卫星导航定位新技术及高精度数据处理方法[M].武汉大学出版社,2009:34-36页
[51]吴继忠,李明峰,吴玮.利用双频载波双差相关性进行周跳探测[J].南京工业大学学报(自然科学版),2007,(04):56-58页
[52]生仁军.GPS载波相位定位中周跳探测方法的研究[D].东南大学硕士学位论文.2006:35-36页
[53]田湘.GPS多基线姿态测量系统研究与实现[D].南京航空航天大学硕士学位论文.2007:41-42页
[54]李跃军,阎超.飞行器姿态角解算的全角度双欧法[J].北京航空航天大学学报,2007,(05):118-119页
[55]史广青,卢欣,武延鹏等.基于星敏感器的两种姿态确定算法比较分析[J].空间控制技术与应用,2009,35(5):61-63页
[56]王立红,郝继平,汤云.基于最小二乘法的GPS多天线测姿及精度分析[J].测试技术学报,2007,(01):330-332页
[57]肖松,刘朝山,马涛.基于弹载双视场星敏感器求解姿态的几种算法研究[J].光学技术,2008,34:218-220页
[58]杜春花,范胜林,袁信.一种基于GPS的测姿新方法[J].南京航空航天大学学报,2002,(04):122-126页
[59]马艳红,胡军.姿态四元数相关问题[J].空间控制技术与应用,2008,(03):56-59页
[60]周亢,闫建国,屈耀红.全角度姿态角解算方法研究与仿真[J].系统仿真学报,2009,(6):1697-1700页
[61]李康,黄胜,赵辉.GPS坐标系的转换及其在姿态求解中的应用[J].指挥控制与仿真,2008,(05):540-543页
[62]刘立龙.动态对动态GPS高精度定位理论及其应用研究[D].武汉大学硕士学位论文.2005:36-40页
[63]周连秋.COM组件的应用[J].电脑学习,2006(01):51-52页
[64]范晖.VC与MATLAB的混合编程[J].现代电子,2001(1):21-25页
[65]戚科骏,宰金珉,梅国雄.C++和Matcom混合编程在数值计算编程的应用[J].南京建筑工程学院学报,2002(4):32-35页
[66]袁建平,罗建军,岳晓奎等.卫星导航原理与应用[M].中国宇航出版社,2004:150-154页
[2]贺智轶.基于GPS动态载体姿态测量系统的研究与应用[D].武汉理工大学硕士学位论文.2006:1页
[3]马鲲.GPS船舶姿态测量技术研究[D].大连海事大学硕士学位论文.2004:1页
[4]韩慧群.GPS姿态测量系统研究与开发[D].哈尔滨工程大学硕士学位论文.2005:2-3页
[5]李跃.导航与定位(第二版)[M].国防工业出版社,2008:20-21页,112-115页
[6]伍岳.第二代导航卫星系统多频数据处理理论及应用[D].武汉大学硕士学位论文.2005:3-4页
[7]王海涛.基于北斗双星定位系统的精密快速定向技术研究[D].国防科学技术大学硕士学位论文.2006:6-9页
[8]吴美平,逯亮清.北斗双星系统车辆定向技术[J].国防科技大学学报,2006,(03):612-614页
[9]孙希延,纪元法,施浒立.基于GPS的新测姿算法[J].全球定位系统,2006,(03):56-59页
[10]刘鹏辉.GPS姿态测量及整周模糊度技术研究[D].中北大学硕士学位论文.2007:5-6页,4页
[11]赵文晔.基于双天线的GPS测姿系统研究[D].苏州大学硕士学位论文.2009:3页
[12]刘瑞华,张鹏.基于改进LAMBDA算法的GPS载波相位测姿技术研究[J].航天控制,2010,(03):98-102页
[13]王艳,伍吉仓,胡丛玮.一种GPS整周模糊度解可靠性的估计方法[J].大地测量与地球动力学,2009,(05):27-30页
[14]田湘,范胜林,刘建业.基于GPS的多基线姿态系统研究[J].航天控制,2008,(02):23-26页
[15]张健.基于GPS的航天器姿态确定研究[D].哈尔滨工业大学硕士学位论文.2009:4-5页
[16]Juang J C, Huang G S. Development of GPS-based attitude determination algorithms. 1997 (03):201-205P
[17]张守信.GPS技术与应用[M].国防工业出版社,2004:6页,127-144页,192-198页,111-112页
[18]韦峰.GPS测量的应用研究[D].西安科技大学硕士学位论文.2007:6-7页
[19]刘若普.GPS三维姿态测量技术研究[D].上海交通大学硕士学位论文.2008:6-8页
[20]Phatak M S. Recursive method for optimum GPS strellite selection[J]. IEEE Transactions of Aerospace and Electronic Systems,2001,37 (2):751-754P
[21]陈石磊.GPS载波相位定位技术的研究[D].西安电子科技大学硕士学位论文.2008:6页
[22]郭婧.基于GPS的姿态测量技术研究[D].哈尔滨工程大学硕士学位论文.2009:12-14页
[23]许江宁,朱涛,卞鸿巍.GPS姿态测量技术综述[J].海军工程大学学报,2003,(03):17-22页
[24]郭兴华.GPS动态实时定位技术研究[D].哈尔滨工程大学硕士学位论文.2007:17-19页
[25]孙希延,纪元法,施浒立.基于GPS的新测姿算法[J].全球定位系统,2006,(03):39-41页
[26]崔铭.基于GPS的姿态测量算法研究[D].哈尔滨工程大学硕士学位论文,2008:32-33页
[27]陈琳.GPS姿态测量系统的研究[D].重庆大学硕士学位论文.2007:14-16页
[28]李康,黄胜,赵辉.GPS坐标系的转换及其在姿态求解中的应用[J].指挥控制与仿真,2008,(05):99-102页
[29]陆维维.GPS动态载波相位测量技术研究及应用[D].河海大学硕士学位论文.2006:17-18页
[30]许春明.GPS动态载波相位测量定位技术研究[D].哈尔滨工程大学硕士学位论文.2002:37-40页
[31]Ellis J F, Greswell G A. Interferometric attitude determination with the Global Positioning System. Journal of Guidance and Control.1979,12:523-527P
[32]赵琳.卫星导航系统[M].哈尔滨工程大学出版社,2001:121-124页
[33]刘基余.GPS卫星导航定位原理与方法[M].科学出版社,2006:369-376页
[34]杨铁军.GPS实时姿态测量技术与多径误差研究[D].电子科技大学硕士学位论文.2003:18-20页
[35]刘军承.GPS姿态确定技术[D].华北工学院硕士学位论文.2002:39-42页
[36]Juang J C, Huang G S. Development of GPS-based attitude determination algorithms.1997, (03):42-46P
[37]廖向前,黄顺吉,张晓玲.GPS双基线载体姿态测量研究[J].航空学报,1998,(05):531-535页
[38]王惠南,应金栋.GPS载体姿态测量中的LAMBDA方法研究[J].航空学报,2001,(01):61-63页
[39]史琳.GPS整周模糊度及其在姿态测量中的应用研究[D].武汉理工大学硕士学位论文.2008:43-48页
[40]张旭.GPS载波相位定位算法研究与仿真[D].哈尔滨工程大学硕士学位论文.2007:45-47页
[41]王仁谦.GPS动态定位的理论研究[D].中南大学硕士学位论文.2004:39-44页
[42]李建文.GLONASS卫星导航系统及GPS/GLONASS组合应用研究[D].解放军信息工程大学硕士学位论文.2001:38-40页
[43]P.J.G.Teunissen, P.J.de Jonge, C.C.J.M.Tiberius. The least-squares ambiguity decorrelation austment:its performance on short GPS baselines and short observation spans, Journal of Geodesy 1997 (71):589-602
[44]郑庆晖,张育林.GPS姿态测量的载波相位整周模糊度快速解算[J].航空学报,2002,(03):113-116页
[45]Chang XW, Yang X, Zhou TY. MLAMBDA:A modified LAMBDA method for integer least-squares estimation. School of Computer Science, McGill UniveBity, 2005:1-20P
[46]林雪原,田淑荣,陈玉林.一种GPS整周模糊度的解算方法[J].海军航空工程学院学报,2008,(01):112-114页
[47]范胜林等.GPS姿态系统中周跳的检测及修复方法[J].数据采集与处理,2002,(1):50-53页
[48]李江卫.GPS相位观测值中周跳的探测与修复算法研究[D].武汉大学硕士学位论文.2004:31-34页
[49]Rizos.C, Lichtenegger.H and B.Hofinarm-Wellenhof. GPS-data proeessing for cycle-slip detection. International Association of Geodesy Symposium 102,1999 Edinburgh, Scotland,2-8 August 1989:57-68P
[50]李航征,张小红.卫星导航定位新技术及高精度数据处理方法[M].武汉大学出版社,2009:34-36页
[51]吴继忠,李明峰,吴玮.利用双频载波双差相关性进行周跳探测[J].南京工业大学学报(自然科学版),2007,(04):56-58页
[52]生仁军.GPS载波相位定位中周跳探测方法的研究[D].东南大学硕士学位论文.2006:35-36页
[53]田湘.GPS多基线姿态测量系统研究与实现[D].南京航空航天大学硕士学位论文.2007:41-42页
[54]李跃军,阎超.飞行器姿态角解算的全角度双欧法[J].北京航空航天大学学报,2007,(05):118-119页
[55]史广青,卢欣,武延鹏等.基于星敏感器的两种姿态确定算法比较分析[J].空间控制技术与应用,2009,35(5):61-63页
[56]王立红,郝继平,汤云.基于最小二乘法的GPS多天线测姿及精度分析[J].测试技术学报,2007,(01):330-332页
[57]肖松,刘朝山,马涛.基于弹载双视场星敏感器求解姿态的几种算法研究[J].光学技术,2008,34:218-220页
[58]杜春花,范胜林,袁信.一种基于GPS的测姿新方法[J].南京航空航天大学学报,2002,(04):122-126页
[59]马艳红,胡军.姿态四元数相关问题[J].空间控制技术与应用,2008,(03):56-59页
[60]周亢,闫建国,屈耀红.全角度姿态角解算方法研究与仿真[J].系统仿真学报,2009,(6):1697-1700页
[61]李康,黄胜,赵辉.GPS坐标系的转换及其在姿态求解中的应用[J].指挥控制与仿真,2008,(05):540-543页
[62]刘立龙.动态对动态GPS高精度定位理论及其应用研究[D].武汉大学硕士学位论文.2005:36-40页
[63]周连秋.COM组件的应用[J].电脑学习,2006(01):51-52页
[64]范晖.VC与MATLAB的混合编程[J].现代电子,2001(1):21-25页
[65]戚科骏,宰金珉,梅国雄.C++和Matcom混合编程在数值计算编程的应用[J].南京建筑工程学院学报,2002(4):32-35页
[66]袁建平,罗建军,岳晓奎等.卫星导航原理与应用[M].中国宇航出版社,2004:150-154页